Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0948265 (metabolic syndrome)
 24,271 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Circulating plasma adiponectin, an adipocyte-derived protein, has been shown to be decreased in obese subjects as well as in patients with type 2 diabetes and also in subjects who do not have diabetes, but are insulin resistant. We assessed the relationship between plasma levels of adiponectin, the metabolic syndrome and the occurrence of small dense LDL particles (pattern B) in 101 clinically healthy middle-aged subjects recruited from the general population. Low adiponectin levels were associated with the metabolic syndrome and low-density lipoprotein (LDL) particle size (r =.55, P <.001). The relationship between adiponectin and LDL particle size remained in a multiple regression model, in which adiponectin and total body fat explained 30% of the variability in LDL particle size. Furthermore, subjects in the lowest tertile of adiponectin had an increased risk of having pattern B (risk odds ratio [ROR] = 5.6). Because this was a cross-sectional study, no conclusions can be drawn about causality. This is the first population-based study in man demonstrating a relationship between small dense LDL particles and adiponectin.
Metabolism 2003 Dec
PMID:Low adipocyte-derived plasma protein adiponectin concentrations are associated with the metabolic syndrome and small dense low-density lipoprotein particles: atherosclerosis and insulin resistance study. 1466 65

The metabolic syndrome involves multiple and interactive effects of genes and environmental factors. To identify chromosomal regions encoding genes possibly predisposing to the metabolic syndrome, we performed a genome-wide scan with 456 white and 217 black participants from 204 nuclear families of the HERITAGE Family Study, using regression-based, single- and multipoint linkage analyses on 509 markers. A principal component analysis was performed on 7 metabolic syndrome-related phenotypes. Two principal components, PC1 and PC2 (55% of the variance), were used as metabolic syndrome phenotypes. ANOVA was used to quantify the familial aggregation of PC1 and PC2. Family membership contributed significantly (P < 0.0023) to the variance in PC1 (r(2) = 0.38 in whites; r(2) = 0.55 in blacks) and PC2 (r(2) = 0.51; r(2) = 0.48). In whites, promising evidence for linkage (P < 0.0023) was found for PC1 (2 markers on 10p11.2) and PC2 (a marker on 19q13.4). Suggestive evidence of linkage (0.01 > P > 0.0023) appeared for PC1 (1q41 and 9p13.1) and PC2 (2p22.3). In blacks, promising linkage was found for PC2 on 1p34.1, and suggestive linkage was found on 7q31.3 and 9q21.1. The genome-wide scan revealed evidence for quantitative trait loci on chromosomal regions that have been previously linked with individual cardiovascular disease and type 2 diabetes risk factors. Some of these chromosomal regions harbor promising potential candidate genes.
J Clin Endocrinol Metab 2003 Dec
PMID:Genome-wide linkage scan for the metabolic syndrome in the HERITAGE Family Study. 1467 Nov 93

Patients with type 2 diabetes mellitus or the metabolic syndrome have a unique dyslipidemia characterized by hypertriglyceridemia; elevated blood levels of apolipoprotein B; small, dense low-density lipoprotein (LDL) cholesterol; and low levels of high-density lipoprotein (HDL) cholesterol, in particular HDL(2)-C. Treatment of the dyslipidemia associated with these disorders should focus on correcting the abnormal lipoprotein levels as well as LDL and HDL heterogeneity. Statins and fibrates are useful for treating elevated LDL in patients with and without diabetes or the metabolic syndrome. In addition, thiazolidinediones or niacin in combination with a statin show promise for correcting defects in LDL and HDL heterogeneity. The ultimate goal of treatment in this patient population is to prevent the development and progression of coronary artery disease.
Am J Med 2003 Dec 08
PMID:Dyslipidemia in the metabolic syndrome and type 2 diabetes mellitus. 1467 62

Concentrations of plasminogen activator inhibitor-1 (PAI-1) are elevated beginning at the stage of impaired glucose tolerance and continuing through the development of diabetes mellitus and the metabolic syndrome. Evolving evidence of the central role of PAI-1 in mediating fibrosis and thrombosis increasingly supports the theory that it is a significant risk factor for macrovascular complications and cardiovascular disease, particularly in patients with diabetes. Several clinical studies have demonstrated a strong correlation between circulating PAI-1 levels and cardiovascular events and mortality. With the potentially severe effects of elevated PAI-1 levels becoming evident, there is increased interest in developing therapies targeted at reducing PAI-1 expression or circulating concentrations. Thus far, weight loss, inhibitors of the renin-angiotensin system, and insulin sensitization through use of thiazolidinediones (TZDs) appear to be the most promising strategies for managing elevated PAI-1 levels. Of these, TZD therapy is the only one that provides the benefits of both long-term glycemic control and improved cardiovascular risk profile. This article reviews the regulation of PAI-1, its activity in various disease states, and available treatment options.
Am J Med 2003 Dec 08
PMID:Effect of plasminogen activator inhibitor-1 in diabetes mellitus and cardiovascular disease. 1467 68

The vascular endothelium is an active, dynamic tissue that controls many important functions, including regulation of vascular tone and maintenance of blood circulation, fluidity, coagulation, and inflammatory responses. Cardiovascular risk factors affect many of the normal functions of the endothelium. In particular, oxidized low-density lipoprotein cholesterol initiates a series of events that begin with cell activation, endothelial dysfunction, local inflammation, and a procoagulant vascular surface. These conspire to result in plaque formation and ultimately plaque rupture and cardiovascular events. Endothelial dysfunction may be evaluated by means of invasive techniques, such as coronary artery reactivity to acetylcholine, or noninvasive techniques, such as brachial artery ultrasonography. Loss of endothelium-dependent vasodilation is a characteristic feature throughout the development of atherosclerosis, and it is independently related to future adverse cardiovascular risk. Therefore, measurement of endothelial function can possibly be used to determine risk, to triage management, and to improve outcomes. At the same time, inflammation is a crucial factor in the atherosclerotic disease process. To identify and monitor the ongoing inflammatory process, markers of inflammation such as C-reactive protein (CRP) have been studied. Scientific evidence shows that elevated plasma CRP values add to the predictive ability of other established risk factors; moreover, elevated values appear to augment the Framingham Coronary Risk Score in identifying individuals who should be considered for cardioprotective treatment programs. Interestingly, thiazolidinediones (TZDs), peroxisome proliferator-activated receptor-gamma agonists that are effective in the treatment of type 2 diabetes mellitus, not only increase insulin sensitivity but can benefit endothelial function because they exhibit anti-inflammatory effects. For many individuals, including those with the metabolic syndrome and/or type 2 diabetes, endothelial dysfunction and elevated plasma CRP levels indicate increased risk of cardiovascular disease. Notably, the TZDs have been shown to reduce CRP levels and may improve endothelial function.
Am J Med 2003 Dec 08
PMID:Endothelial function, inflammation, and prognosis in cardiovascular disease. 1467 74

Genome-wide scanning is a powerful tool to identify susceptible chromosome loci, however, individual chromosomal regions still have many candidate genes. Although cDNA microarray analysis provides valuable information for identifying genes involved in pathogenesis, expression levels of many genes are changed. A novel approach for identification of therapeutic targets is the combination of genome-wide scanning and the use of DNA chips, as shown in Fig. (1). Using DNA chips, we screened for secreted molecules, the expressions of which were changed in adipose tissues from mice rendered insulin resistance. Decreased expression of one of these molecules, adiponectin/Acrp30, correlates strongly with insulin resistance. Interestingly, recent genome-wide scans have mapped a susceptibility locus for type 2 diabetes and metabolic syndrome to chromosome 3q27, where adiponectin gene is located. Decreasing serum adiponectin levels are associated with increased risk for type 2 diabetes. Interestingly, adiponectin was decreased in insulin resistant rodent models both of obesity and lipoatrophy, and replenishment of adiponectin ameliorated their insulin resistance. Moreover, adiponectin transgenic mice ameliorated insulin resistance and diabetes Adiponectin knockout mice showed insulin resistance and glucose intolerance. In muscle and liver, adiponectin activated AMP kinase and PPARalpha pathways thereby increasing beta-oxidation of lipids, leading to decreased TG content, which ameliorated insulin resistance under a high-fat diet. Despite similar plasma glucose and lipid levels on an apoE deficient background, adiponectin transgenic apoE deficient mice showed amelioration of atherosclerosis, which was associated with decreased expressions of class A scavenger receptor and tumor necrosis factor alpha. Finally, cDNA encoding adiponectin receptors (AdipoR1 and R2) have been identified by expression cloning, which facilitates the understanding of molecular mechanisms of adiponectin actions and obesity-linked diseases such as diabetes and atherosclerosis and the designing of novel antidiabetic and anti-atherogenic drugs with AdipoR1 and R2 as molecular targets.
Curr Drug Targets Immune Endocr Metabol Disord 2003 Dec
PMID:Dual roles of adiponectin/Acrp30 in vivo as an anti-diabetic and anti-atherogenic adipokine. 1468 55

BACKGROUND AND THERAPY: The metabolic syndrome comprises a virulent and lethal group of atherosclerotic risk factors, including dyslipidemia, obesity, systemic hypertension and insulin resistance. The prevalence of the metabolic syndrome has continuously grown in industrialized and developing countries during the last decades, and affects tens of millions of people in Germany and Europe. Particularly prominent as a risk factor for the development of insulin resistance is central obesity, which is causally involved in the pathogenesis of insulin resistance in addition to genetic predisposition. The metabolic syndrome can easily be diagnosed in clinical practice (guidelines of the WHO and ATP III panel), and immediate treatment of the metabolic syndrome is mandatory because those patients are at increased risk to develop overt diabetes mellitus, coronary artery disease and stroke. The high risk for cardiovascular diseases is supported by findings that the risk for myocardial infarction in patients with insulin resistance is as high as the risk of patients after their first myocardial infarction. Intentional weight reduction reduces abdominal obesity and beneficially modulates all features of the metabolic syndrome, while the benefits of aerobic exercise training are discussed controversially. Thus, weight reduction causally undoes essential features of the metabolic syndrome, but effects are often not enduring. Therefore, the treatment of cardiovascular risk factors such as hypertension and dislipidemia is essential. Of note, antihypertensive treatment is more effective than tight glucose control to reduce cardiovascular events. Diuretics, ACE-inhibitors and angiotensin II type 1 receptor antagonists are suggested as first line therapeutics. However, at least two antihypertensives are usually necessary to achieve the suggested goals of blood pressure reduction. In conclusion, the prevalence of the metabolic syndrome is continuously growing. Due to its adverse impact on cardiovascular disease, early detection and aggressive treatment is mandatory to ensure longlasting benefits for affected patients.
Herz 2003 Dec
PMID:[Arterial hypertension and metabolic syndrome]. 1468 1

The macrophage plays a diverse array of roles in atherogenesis and lipoprotein metabolism. The macrophage functions as a scavenger cell, an immune mediator cell, and as a source of chemotactic molecules and cytokines. Chemokines have been implicated in promoting migration of monocytes into the arterial intima. Monocyte chemoattractant protein-1 (MCP-1) attracts monocytes bearing the chemokine receptor CCR-2. Macrophage expression of cyclooxygenase-2, a key enzyme in inflammation, promotes atherosclerotic lesion formation in low-density lipoprotein receptor (LDLR)-deficient mice. In the arterial intima, monocytes differentiate into macrophages, which accumulate cholesterol esters to form lipid-laden foam cells. Foam cell formation can be viewed as an imbalance in cholesterol homeostasis. The uptake of atherogenic lipoproteins is mediated by scavenger receptors, including SR-A and CD36. In the macrophage, ACAT-1 is responsible for esterifying free cholesterol with fatty acids to form cholesterol esters. Surprisingly, deficiency of macrophage ACAT-1 promotes atherosclerosis in LDLR-deficient mice. A number of proteins have been implicated in the process of promoting the efflux of free cholesterol from the macrophage, including apoE, ABCA1, and SRB-1. Macrophage-derived foam cells express the adipocyte fatty acid-binding protein (FABP), aP2, a cytoplasmic FABP that plays an important role in regulating systemic insulin resistance in the setting of obesity. ApoE-deficient mice null for macrophage aP2 expression develop significantly less atherosclerosis than controls wild type for macrophage aP2 expression. These results demonstrate a significant role for macrophage aP2 in the formation of atherosclerotic lesions independent of its role in systemic glucose and lipid metabolism. Furthermore, macrophages deficient in aP2 display alterations in inflammatory cytokine production. Through its distinct actions in adipocytes and macrophages, aP2 links features of the metabolic syndrome including insulin resistance, obesity, inflammation, and atherosclerosis.
Int J Obes Relat Metab Disord 2003 Dec
PMID:Macrophages, inflammation, and atherosclerosis. 1470 42

Prevention of atherosclerosis in type 2 diabetes ideally should start a long time before the diagnosis of diabetes since type 2 diabetes and atherosclerosis have a common background of metabolic syndrome. Identifying subjects with metabolic syndrome and beginning with lifestyle and drug interventions in such subjects would most probably delay the development of both diabetes and atherosclerosis. After the clinical diagnosis of diabetes, it is necessary to continue with multifactorial interventions targeted on risk factors, such as hyperglycaemia, dyslipidaemia and hypertension. Some interventions appear to have a benefit beyond the effect on risk factors. Effects of these interventions can be explained by their influence on some pathogenic mechanisms, such as insulin resistance and endothelial dysfunction. Multifactorial interventions decrease the incidence of macrovascular disease in diabetes at least by one-half and should be routinely used in the majority of patients with type 2 diabetes.
Acta Diabetol 2003 Dec
PMID:Pharmacological treatment of diabetic patients with respect to prevention of macrovascular disease. 1470 65

Type 2 diabetes is increasing in epidemic proportions worldwide, and is strongly associated with atherosclerotic cardiovascular disease (CVD). Hyperglycaemia increases risk of CVD, but glycaemic control does not substantially reduce CVD risk. There are several potential explanations for this apparent paradox, including the roles of the metabolic syndrome and post-load hyperglycaemia in the association of type 2 diabetes and CVD.
Acta Diabetol 2003 Dec
PMID:Epidemiology of cardiovascular complications in type 2 diabetes mellitus. 1470 69


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